CN111147832B - Projector display system - Google Patents
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- CN111147832B CN111147832B CN201911258354.5A CN201911258354A CN111147832B CN 111147832 B CN111147832 B CN 111147832B CN 201911258354 A CN201911258354 A CN 201911258354A CN 111147832 B CN111147832 B CN 111147832B
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Abstract
Disclosed is a projector display system including: a light source; a controller that receives input image data and transmits a control signal in response to the input image data; a first modulator controllable by the control signal from the controller and configured to generate a blurred image based on the input image data; a relay optical system configured to receive a blurred image from the first modulator and further configured to provide a desired amount of defocus of the blurred image to provide a plurality of substantially Gaussian spots; and a second modulator configured to receive the plurality of gaussian spots and further modulate the light to produce an image for further projection.
Description
The present application is a divisional application of the chinese invention patent application having an application date of 2015, 12/23, international application numbers of PCT/IB2015/059957, chinese application number of 201580071748.3, entitled "method and system for high dynamic range image projector".
Cross Reference to Related Applications
This application claims priority from U.S. patent application No. 62/142,353 filed on day 4, month 2, 2015 and U.S. provisional patent application No. 62/099,078 filed on day 12, month 31, 2014, each of which is incorporated herein by reference in its entirety.
Technical Field
The present invention relates to light recycling for projector systems, and in particular to systems and methods for High Dynamic Range (HDR) projection systems.
Background
Projector systems are now being built by improving the dynamic range. Dual-modulator and multi-modulator projector display systems are known in the art. However, improved modeling of light processing in such display systems results in additional improvements being possible in both the presentation and performance of such display systems. Furthermore, as understood by the present inventors, it is desirable to increase the brightness of image highlights for dual modulation/multi modulation systems, and/or the energy performance of single modulation display systems as well as dual modulation/multi modulation display systems.
Disclosure of Invention
Projection systems and/or methods are disclosed that efficiently utilize light by recycling a portion of the light energy for future use. In one embodiment, a projection display system is disclosed, comprising: a light source; an integrating rod receiving light from a light source at a proximal end, the proximal end including a reflective surface that can reflect/recover light along the integrating rod; and a modulator comprising at least one movable mirror that reflects light received from the integrator rod in either a projection direction or a light recovery direction. In other embodiments, dual and multi-modulator projector display systems are disclosed. The first modulator may affect a pre-modulated halftone image or may affect a highlight modulation image for a desired image to be displayed. A second modulator may be provided for primary modulation of the desired image.
In one embodiment, a projector display system capable of recycling light from a light source is disclosed, the projector display system comprising: a light source; an integrating rod configured to receive light from the light source at a proximal end, and wherein the proximal end comprises a reflective surface capable of reflecting light along the integrating rod; reflecting light along said integrating rod; a relay optical system further comprising an optical element capable of moving a focal plane of the projector display system; and a modulator comprising a movable mirror capable of reflecting light received from the integrating rod in at least one of a projection direction and a light recovery direction, wherein the light recovery direction is substantially along the direction of the integrating rod.
Embodiments are also presented for controlling light recycling in response to image characteristics.
Other features and advantages of the present system are presented in the following detailed description when read in conjunction with the figures presented in this application.
Drawings
Exemplary embodiments are shown in the various figures of the drawings. The purpose is as follows: the embodiments and figures disclosed herein are to be regarded as illustrative rather than restrictive.
FIG. 1A depicts a dual modulator projector display system with a light recovery module, schematically illustrated and fabricated according to the principles of the present application.
FIG. 1B depicts a single modulation projector display system with a light recovery module, schematically illustrated and fabricated according to the principles of the present application.
FIG. 1C depicts a projector display system including light recovery modules on multiple color channels.
FIG. 2 depicts one embodiment of a light recovery module that meets the objectives of the present application.
FIG. 3 shows the proximal end of an integrating rod suitable for the purposes of the present application.
Fig. 4 depicts another embodiment of a dual modulator/multi-modulator projector system in accordance with the principles of the present application in which it may be possible and/or desirable to perform light recycling.
Fig. 5 depicts another embodiment of a projector system in accordance with the principles of the present application in which recycling light may be possible and/or desirable.
Fig. 6A and 6B schematically depict many possible embodiments for a projector system that may provide these one or more opportunities for light recycling, according to principles of the present application.
Fig. 7A is a possible light recycling control system and/or method for a single modulation projector display system.
Fig. 7B and 7C depict a response curve and a response table, respectively, for each modulated color response of a conventional DMD component.
Fig. 8 depicts another possible light recycling control system and/or method for a single modulation projector display system.
Fig. 9 depicts yet another possible light recycling control system and/or method for a single modulation projector display system.
Fig. 10 depicts one possible response table for light recycling for a given illumination pattern.
Fig. 11, 12 and 13 depict three algorithms for efficient light recycling in a display system where light recycling can be performed.
FIG. 14 depicts an alternative embodiment of a light recycling module in a dual modulator display system.
Fig. 15 depicts one possible gaussian spot shape produced by relay optics made in accordance with the principles of the present application.
Fig. 16 is another embodiment of a relay optical system made in accordance with the principles of the present application.
FIG. 17 depicts one embodiment of a focusing lens group within the relay optical system of FIG. 16.
Fig. 18 shows one embodiment of a coma correcting lens group in the relay optical system of fig. 16.
Fig. 19 depicts one embodiment of a relay optical system that may be suitable for use in a projector system that may perform light recycling.
Fig. 20 depicts an exemplary plot of fiber count versus (vs.) recovery efficiency for a hypothetical projector display system.
Detailed Description
As used herein, the terms "component," "system," "interface," and the like are intended to refer to a computer-related entity, either hardware, software (e.g., in execution), and/or firmware. For example, a component may be a process running on a processor, an object, an executable, a program, and/or a computer. By way of illustration, both an application running on a server and the server can be a component. One or more components may reside within a process and a component may be localized on one computer and/or distributed between two or more computers. Components may also be intended to refer to communication-related entities, i.e., hardware, software (e.g., in execution), and/or firmware, and may also include sufficient wired or wireless hardware to affect communication.
Specific details are set forth in the following description in order to provide a more thorough understanding to persons skilled in the art. However, well known elements may not have been shown or described in detail to avoid unnecessarily obscuring the disclosure. The specification and drawings are, accordingly, to be regarded in an illustrative rather than a restrictive sense.
Introduction to
In the field of projectors and other display systems, it is desirable to improve image rendering performance and system efficiency. Several embodiments of the present application describe systems, methods, and techniques to affect these improvements by employing light field modeling for dual or multi-modulation display systems. In one embodiment, a light source model is developed and used for beneficial effects. A camera picture of a displayed image of a known input image may be evaluated to improve the light model. In some embodiments, the iterative process may accumulate improvements. In some embodiments, these techniques may be used for moving images for real-time modulation to improve image rendering performance.
Dual modulation projector and display systems are described in the following commonly owned patents and patent applications, including:
(1) U.S. patent No. 8,125,702 to Ward et al, issued on 28.2.2012, entitled "SERIAL MODULATION DISPLAY HAVING BINARY LIGHT MODULATION STAGE";
(2) U.S. patent application 20130148037 to Whitehead et al, entitled "PROJECTION DISPLAYS," published on 13.6.2013;
(3) U.S. patent application No. 20110227900 to Wallener, entitled "CUSTOM PSFs USING CLUSTERED LIGHT SOURCES", published 22.9.2011;
(4) U.S. patent application 20130106923 to Shields et al, entitled "SYSTEMS AND METHODS for screening REPRESENTING HIGH control image ON HIGH DYNAMIC RANGE DISPLAY SYSTEMS", published 5, 2.2013;
(5) U.S. patent application No. 20110279749 to Erinjippurath et al, entitled "HIGH DYNAMIC RANGE DISPLAYS USING FILTERLESS LCD (S) FOR INCEASING CONTRAST AND RESOLUTION", published 17.11.2011; and
(6) kwong's U.S. patent application 20120133689, entitled "REFLECTORS WITH SPATIALLY VARYING REFLECTANCE/ABSORPTION GRADIENT FOR COLOR AND LUMINANCE COMPENSATION", was published on 31/5/2012.
The entire contents of the above application are incorporated herein by reference.
An exemplary physical architecture
Generally, projectors with a single Digital Micromirror Device (DMD) may tend to have limited contrast. To obtain greater contrast, two or more DMDs and/or other reflectors (e.g., micro-electromechanical systems (MEMS)) may be arranged in series. Since a DMD may operate as a time-division or pulse-width modulator, operating two or more DMDs and/or reflectors in series (both acting as pulse-width modulators) often requires precise time-division alignment and time-division ordered pixel-to-pixel correspondence. Such alignment and correspondence requirements may be difficult in practice. Thus, in many embodiments of the present application, the projector and/or display system may employ different dual modulation schemes to affect the desired performance.
For but one example, one embodiment of a projector display system may use a first modulator (e.g., a first DMD/reflector) as a "pre-modulator or premod" that may spatially modulate a light source with a halftone image that may be maintained for a desired period of time (e.g., a frame or portion of a frame). The halftone image may be blurred to produce a spatially reduced-bandwidth (spatial-reduced-bandwidth) light field that may be applied to a second DMD/reflector. A second DMD/reflector, referred to as the primary modulator, may pulse width modulate the blurred light field. Such an arrangement may tend to avoid the two requirements mentioned above, e.g., precise time division alignment and/or pixel-to-pixel correspondence. In some embodiments, two or more DMD/reflectors may be frame aligned in time and substantially frame aligned in space. In some embodiments, the blurred light field from the pre-DMD/reflector may substantially overlap the primary DMD/reflector. In other embodiments, the spatial alignment may be known and considered, for example, to assist in image rendering performance.
While the present application is presented in the context of a dual modulation, multi-modulation projection system, it should be understood that the techniques and methods of the present application will find application in single modulation or other dual modulation, multi-modulation display systems. For example, a dual modulation display system including a backlight, a first modulator (e.g., LCD, etc.), and a second modulator (e.g., LCD, etc.) may employ suitable blurring optics and image processing methods and techniques to affect the performance and efficiency discussed herein in the context of a projection system.
It should also be understood that while fig. 1A depicts a two-level or dual modulator display system, the methods and techniques of the present application may also be applied to display systems having only one modulator or display systems having three or more modulators (multi-modulator display systems). The scope of the present application includes such various alternative embodiments.
Fig. 1A illustrates one possible implementation of a dual modulator/multi-modulator projector display system 100 that may meet the objectives of the present application. Projector system 100 employs a light source 102 that provides the desired illumination for the projector system so that the final projected image is sufficiently bright for the intended viewer of the projected image. Light source 102 may include any suitable light source possible, including but not limited to: xenon lamp, laser, coherent light source, partially coherent light source. Since the light source is the primary source of power and/or energy for the entire projector system, it is desirable to advantageously use and/or reuse the light to conserve power and/or energy during its operation.
The light 104 may illuminate a first modulator 106, which in turn may illuminate a second modulator 110 via a set of optional optical components 108. Light from the second modulator 110 may be projected by a projection lens 112 (or other suitable optical component) to form a final projected image on a screen 114. The first modulator and the second modulator may be controlled by a controller 116, and the controller 116 may receive input image and/or video data. The controller 116 may perform certain image processing algorithms, gamut mapping algorithms, or other such suitable processing on the input image/video data and output control/data signals to the first and second modulators to achieve the desired final projected image 114. Further, in some projector systems, the light source 102 may be modulated according to the light source (control lines not shown) to enable additional control over the image quality of the final projected image.
In fig. 1A, the light recycling module 103 is depicted as a dashed box, and the light recycling module 103 may be placed in the light path from the light source 102 to the first modulator 106, as will be discussed below. Although the discussion of the present invention will be given in the context of such an arrangement, it should be understood that in a projector system, light recycling may be inserted at various points in the projector system. For example, light recycling may be placed between the first modulator and the second modulator. Furthermore, light recycling may be placed at more than one point in the light path of the display system. While such an embodiment may be more expensive due to an increase in the number of components, such an increase may be balanced with savings in energy costs due to multi-point light recycling.
FIG. 1B depicts one embodiment of a projector display system 100B that includes a single modulator 106B. As previously described, the light source 102b emits (possibly under control of a controller — not shown) a light beam 104b, which light beam 104b may pass through the light recovery module 103 b. The modulator 106b may selectively reflect light as required by the controller, and the modulated light 108b may pass through projector optics 112b and be projected onto a screen 114 as the final desired image to be viewed.
Fig. 1C depicts one embodiment of a light recovery module that can perform light recovery on multiple color laser channels (e.g., R, G and B). As can be seen in this example, the display system may include a red light source (R) that enters integrator rod 126 (e.g., B enters integrator rod 124 and G enters integrator rod 122), and the red light may be transmitted (possibly via total internal reflection) to a controllable reflector 120, which reflector 120 may include one or more reflectors that may exhibit either a recycling position 120B or a transmitting position 120 a. If light is to be recovered, reflector 120b reflects the laser light back into integrator rod 126 — the light may be reflected multiple times within the path until the reflector is commanded (via a controller, not shown) to transport position 120 a. The light transmitted by reflector 120a may be directed toward a red mirror 128 as shown. In the case of blue light, the blue light may be combined with red light at a dichroic combiner (dichroic combiner) 130. Similarly, the green light may thereafter be combined at a dichroic combiner 132, and the light may then be further modulated and/or projected by an optical element 120, as simply depicted. It will be appreciated that such a light recycling module may serve the desired purpose of a single modulator, dual modulator, and/or multi-modulator display system.
Light recovery embodiment
Fig. 2 depicts one embodiment of a light recovery subsystem and/or module that may be suitable for the purposes of the present application. As described above, the light recycling subsystem/module may be placed primarily between the light source 102 and the first modulator 221 in a projector system. Light from the light source 102 can be input to the optical path via an integrating rod/tube/box 202 (e.g., via port 201b, as shown in fig. 3). The integrating rod/tube/box 202 can include a substantially reflective surface on its interior such that light incident on its surface can be reflected (e.g., possibly multiple times) until it exits its rightmost end 203. Once the light exits the integrator rod/tube/box, the light may be placed in the optical path defined by a set of optical elements (e.g., lenses 204, 214, and 216) and a set of filters and/or polarizers 208, 210, and 212.
The first modulator 221 may include a number of prisms 218a, 218b and a reflector 220. Reflector 220 may include a DMD array of reflectors, or a MEMS array, or possibly any other suitable set of reflectors that may reflect light in at least two or more paths. One such path is shown in fig. 2. As can be seen, the reflector 220 directs light onto the interface of the prisms 218a and 218b such that the light is thus reflected into the lens assembly 222 and then reflected to the second modulator 229 (e.g., including the lens assembly 224, the prisms 226 and 230, and the reflector 228). These lights may be employed to form a final projected image for viewing by a viewer.
However, at some time during the presentation of the final projected image, the full power/energy of the light source 102 may not be required. If the power of the light source 102 cannot be modulated (or if it is difficult to modulate, or there is another opportunity to save light), it may be desirable to recycle light from the light source 102. In this case, as can be seen in fig. 2, reflector 220 may be aligned from its current position as shown (i.e., the position where light is directed to travel along a path down to the second modulator) to the following positions: in this position, the light will be substantially reflected back to the integrator rod/tube/box 202, following substantially the same path as described when traveling in the right-to-left direction. In one embodiment, the recycling system can make certain portions of the image brighter. This may be desirable in situations where most of the screen is dark and some parts are very bright.
In another embodiment, a third (optional) path (not shown) allows the reflector to direct light from the light source to a light "collector" (dump), i.e., the portion of the projector system that absorbs light. In this case, the light is wasted as heat dissipated from the projector system. Thus, the projector system may have multiple degrees of freedom when it comes to directing light as desired.
Fig. 3 illustrates one embodiment of a proximal end 201 (i.e., the end closest to the light source) that helps affect light recycling. As can be seen in fig. 3, light may travel (e.g., via multiple reflections) through the integrating rod/tube/cartridge 202 back to the proximal end 201. The proximal end 201 may also include a rear portion 201a (the rear portion 201a may also include a reflective surface) and a port opening 201b where light from the light source 102 may be input into the projector system. Light impinging on rear portion 201a may be reflected back to integrator rod 202 (possibly multiple times until a reflector at the first modulator is oriented to transmit light to the second modulator or some other suitable optical path to form the final image). The example of fig. 2 and 3 may be considered one example of a light recycling module (as other examples given herein) that is capable of recycling light at some point in the light path through a display system.
Fig. 14 is another embodiment of a light recovery module 1400, which light recovery module 1400 may provide a module for at least one laser and/or partially coherent colored light source 1402, 1404, 1406. Light from such a light source may pass through first optical subsystem 1408 to condition the light for input into integrating rod 1412, which may include a reflective proximal end 1410 as shown in fig. 3. The second optical subsystem 1414 may further condition the light as needed before input to the first modulator 1416. As shown in fig. 2 and 3 above, the first branch of the module 1400 may affect the light recycling mode in question.
After the first modulation, the light may pass through a third optical subsystem 1418 before being input to a second modulator 1420, the second modulator 1420 modulating the light for passing through a projector optical subsystem 1422 to project a final image for viewing.
High light embodiment
In one embodiment, an optional high light modulator (highlighters modulator) may use a portion of the available light to affect adjustable illumination unless the high light modulator is combined with a pre-modulator. To achieve this, both mechanical and/or non-mechanical subsystems and beam steering (beam steering) techniques may be employed, for example, mechanical steering is used to steer portions of the illumination source to various paths in the system, holograms with spatial light modulators, or other spatial modulation methods are possible. Such systems may need to improve efficiency by diverting light to a desired location.
Mechanical beam steering may use a set of reflective elements that can be controlled over a range of motion in a horizontal direction and/or a vertical direction. As high light modulators produce controlled non-uniform illumination, the reflective elements direct light that reaches the reflective elements to desired areas of the modulator.
Non-mechanical beam steering methods may use a spatial light modulator to shift the phase of the uniform coherent light reaching the modulator. When imaged through a lens, the phase shifted light produces a three dimensional light field. The three-dimensional light field may be imaged as a two-dimensional light field with different planes according to a dimension collapsed imaging (collapsed dimensional imaging) with different sharpness or PSF characteristics, imaged onto one of the subsequent modulators generating the two-dimensional light field.
Regardless of implementation, high light modulation refers to the use of a modulator to divert light arriving at the modulator anywhere on a subsequent modulator. Although there may be limitations such as location range and granularity, the term "anywhere" may still be used to distinguish highlight modulators from other modulators.
In some embodiments, depending on the number of highlight modulating elements, the PSF characteristics, and the total coverage that can be achieved by the highlight modulator, it may not be necessary to have a pre-modulator/first modulator between the highlight modulator and the primary/second modulator. In some embodiments, a high light modulator may have the following properties: i.e. without any modulation (pre-modulation or main modulation) after the highlight modulator.
Control of high light reaching pre/main relay optics
In some embodiments, the relay optics may be adjusted to control the point spread function shape of the illumination produced by the highlight modulator to the pre-modulator/first modulator or the primary modulator/second modulator. In some embodiments, there may be control over adjusting the Full Width at Half maximum (Full Width Half Max) as well as control over the shape or tail of the PSF. When light recovery is employed, it may be desirable to predict, monitor and/or measure the resulting performance, as additional passes through the integrating rod will change the light uniformity and angular diversity, which in turn will affect the resulting PSF.
Pre-modulation/first modulation embodiments
In some embodiments, the pre-modulation/first modulation may require the ability to modulate light arriving at the pre-modulator on its way to the primary modulator. In some cases, pre-modulation may be employed to increase the system contrast. With highlight display, highlight images can illuminate the pre-modulator in addition to the non-imaged pre-modulator illumination.
In some embodiments, a suitable pre-modulator/first modulator may be a DMD, LCD, LCoS (liquid crystal on silicon), or other intensity modulator. Regardless of the implementation, pre-modulation may be used to modulate the arriving light intensity to a subsequent modulator. The pre-modulator elements (e.g., mirrors, pixels, etc.) each affect a fixed location on a subsequent modulator, or on a screen if there is no additional modulation after the pre-modulator. Depending on the number of pre-modulation elements, the PSF properties and the total coverage achievable by the pre-modulator, it may not be necessary to have a primary modulator after the pre-modulator. The pre-modulator may have the following properties: without any modulation (e.g., highlight modulation or main modulation) before or after it.
Relay optics control from pre-modulator to primary modulator
This refers to the ability to adjust the relay optics to control the point spread function shape of the illumination of the primary modulator produced by the highlight modulator or pre-modulator. There is control over adjusting the full width at half maximum and control over the shape or tail of the PSF. A pre-modulator may be used for recycling and it may be desirable to monitor, model, predict and/or measure the resulting illumination intensity, since the additional transfer through the integrating rod will change the light uniformity and angular diversity, which in turn will affect the resulting PSF.
Primary modulator embodiments
Primary/secondary modulation may require the ability to modulate light arriving at the primary modulator en route to the screen. In some embodiments, this may tend to ensure that the resulting image quality has a high contrast and a desired spatial and intensity resolution. In some embodiments, highlight displays and/or pre-modulator images may illuminate the primary modulator in addition to the non-imaged primary modulator illumination.
In some embodiments, a suitable primary/secondary modulator may be a DMD, LCD, LCoS, or other intensity modulator. Regardless of the implementation, the primary/secondary modulation may be used to modulate the arriving light intensity to the screen. Primary modulator elements (e.g., mirrors, pixels, etc.) each affect a fixed position on the screen. The size and shape of each location should be consistent to form a projected screen image, the overall size and shape of which will be determined by the projection optics. Depending on the primary modulator contrast range, it may not be necessary to use a highlight modulator or a premodulator. The primary modulator may have the following properties: i.e. without any modulation (highlight modulation or premodulation) preceding it. Recovery may be performed using a primary modulator. It is desirable to know the resulting illumination intensity horizontally and temporally to compensate with illumination adjustments or to ensure that a desired image is formed by changing the signal to the modulator. The level may be measured. This level can also be modeled and predicted algorithmically.
Other projector System embodiments
Fig. 4 depicts another embodiment of a dual/multi-modulator projector system 400 in which it may be possible and/or desirable to perform light recycling. As can be seen in fig. 4, projector system 400 may include one or more light sources (e.g., 402a and/or 402b or other additional light sources). In this embodiment, the light source 402a provides light into an integration subsystem/box 404a, which may be similar to the embodiment of fig. 2. The light from 402a may eventually reach first modulator 406, where first modulator 406 may be constructed in substantially the same manner as fig. 1A, 1B, 1C, and/or 2 (i.e., with a reflector that may reflect light back to integration subsystem/box 404 a). The light may then travel to optical subsystem 408, second modulator 410, and then to projector lens 412, and may form a final projected image on screen 414.
However, another opportunity for light recycling may occur with another (or in other embodiments, multiple) light source 402 b. In one embodiment, light source 402b may be employed as another primary light source (i.e., to provide a large amount of light for a final image for a large amount of time). In this embodiment, the light from 402b may be further reflected by reflector 403 so that it may be combined with the light from 402a at beam splitter 405, and the combined light beam forms the final image a significant amount of time.
In another embodiment, the light source 402b may be used in a smaller amount of time in order to provide high light illumination within a portion of an image. It should be understood that reflector 403 may be a single mirror that is movable (e.g., to direct light to a collector or another recycling subsystem). Alternatively, reflector 403 may be a group and/or array of reflectors (e.g., MEMS, DMD, etc.) to provide finer control of the additional light from 402 b.
In another embodiment, light source 402b may be optional, and integration subsystem/box 404b may have a fully reflective surface at the proximal end accessible to light source 402 b. In this embodiment, the light may have another path (e.g., within box 404b and within box 404 a) that recovers the light. In another embodiment, a one-way mirror may be used for 405. In this case, reflector 403 would simply be a controllable mirror that can redirect light to 404b, so reflector 403 may only need to "fold" the system for recycling. In such an embodiment, light may not need to be recovered in 404a, but may be recovered in 404 b. This may be desirable because a recycling reflector, which does not have a hole therein for light input, makes it a more efficient recycler.
Fig. 5 is yet another embodiment of possible and/or desirable light recycling. As previously described, projector system 500 may include a light source 502 and an integration subsystem/box 504. Polarizer 505 may be a controllable polarizer, such as an LCD, with polarizer 505 polarizing a selectable portion of the light in one orientation. Beam splitter 506 may be a polarizing beam splitter, and beam splitter 506 passes light in one orientation straight through as a uniform light field 514 for incorporation into primary modulator 518 using 516. Light polarized in the other orientation is redirected 508 by 506. Depending on the design of the system, the mirror 510 may be a mirror for folding the system and shining light to a pre-modulator or highlight modulator 512.
The non-uniform light field from 512 is then combined by 516 and 514 to illuminate 518. When 512 is a pre-modulator, light beam 514 may be used to provide some substantial level of illumination (less than the first step of 512) for very dark portions of image 522 to break out of darkness. Alternatively, when 512 is a high light modulator, 514 is used to provide a uniform illumination level required for image 522 in areas where there are no light rays in the non-uniform light field produced by 512.
In other embodiments, a recycling integrator rod (similar to the integrator rod described in fig. 3) may be placed between 510 and 512 (or between 506 and 510), and a non-recycling version of the integrator rod (e.g., an integrator rod without a back reflector) may be placed between 506 and 516. In such embodiments, it may be desirable to remove 504 after 502 to keep the light as a dense beam (tightbeam).
An illustrative embodiment
Fig. 6A and 6B schematically depict one or more possible implementations of a projector system that may provide these multiple light recycling opportunities. Fig. 6A schematically depicts a process 600 that may be implemented using a dual modulator/multi-modulator projector system. The processing may include light from various lasers, coherent or partially coherent light sources, for example, where the laser light may be pulsed (602) or provided by a laser diode 604. Such light may be combined and transmitted (606) in various architectures and manners (as described in connection with several embodiments above). The light may then be split (608) into component parts (e.g., 610-620), and this light may be combined and split (622) for various functions, such as highlight illumination (628), collector illumination (630), pre-modulated (or first modulator) illumination (626), and main (or second modulator) illumination (624).
In one embodiment, adjusting the laser power tends to uniformly affect the entire display area for global dimming. This may be applicable to some images and scenes in projector systems where the laser and/or light source power may be adjusted. However, in some cases it may be advantageous to have a controllable basic level of uniform illumination applied directly to the highlight, the pre-modulator/first modulator or the primary modulator/second modulator at low brightness levels. Controlling this type of laser power adjustment would be considered another form of global dimming.
In one embodiment where multiple laser sources (a single laser or group of lasers for each controllable source, or by splitting a laser or laser beam into each controllable source) are employed in the display system, the multiple laser sources may be spatially arranged such that each laser source affects a portion of the display area, thereby allowing for local dimming. This approach differs from highlight modulators in that these local dimming regions are spatially fixed, wherein highlight-modulated local dimming regions can be spatially modulated. Mechanical light steering can be used to control laser power adjustment to each region by directing light arriving at the mirror to a spatially directed optical fiber or optical component (e.g., a segmented integrator rod that directs light to a predetermined spatial region on the modulator).
In this case, the mechanical light redirecting means may be considered as part of the laser power adjustment, rather than a high light modulator and/or pre-modulator, however, these systems where the number of individually controllable elements involved in mechanical redirecting is greater than the number of spatial regions have the additional advantage of: that is, the illumination from a fixed light source or a variable light source can be spatially redistributed, rather than having to directly change the light source for each region. The spatial application of laser light to the modulators may be controlled by the illumination optics of each modulator. For global dimming, the illumination of the illumination optics (e.g., lenses, integrating rods, etc.) may be designed to uniformly illuminate the modulator. For local dimming, the illumination of the illumination optics (e.g., lenslet arrays, segmented integrator rods, etc.) can be designed to take each optical path and disperse it into the desired portion of the modulator to produce an appropriate PSF.
In embodiments where the pre-modulator/first modulator is expected to receive most of the illumination, if light recycling is implemented, it may be desirable to make its illumination adjustable, which may reduce contrast, either by splitting or using laser power control, or by using the modulator to compensate.
Several illustrative embodiments
Fig. 6B depicts several embodiments of a projector system that may affect such a process as shown in fig. 6A. The system 632 may optionally provide high light illumination 628 to enter the light path 634 to the high light modulator 636. The light may be sent to the pre-modulator (or first modulator) via optical path 644, or the light may be discarded (638) and may be recycled at 640.
The pre-modulator/first modulator stage may input light via optical path 652 at 626. As described above, this light may be combined with high illumination at the pre-modulator/first modulator 646. This light may be sent to the primary modulator/secondary modulator (e.g., forming a pre-modulated image 654), or may be discarded and recycled at 648.
The primary/secondary modulator (660) may receive light from the pre-modulator/first modulator or the primary illumination 624 (e.g., via optical paths 656, 658, respectively). This light may be sent as a primary image 662 to projection optics 664, forming a projected image 666 (possibly with vibrations if the light source is coherent or partially coherent) on a projection screen 668 and viewed in an auditorium 670 or the like. Otherwise, the light may be discarded and recycled at 674.
It should be understood that the schematic diagram may support a variety of possible projector systems, and that these projector systems are included within the scope of the present application. One or more opportunities may be satisfied that the projector system architecture may support light recycling for purposes of the present application.
Control algorithm implementation
As noted above, it may not be desirable to use the full power of the light source to form the final projected image many times during the projection of an image, a group of images, or a video. In this case, a portion of the light may be recycled multiple times (substantially infinite times) until a brighter image needs to be formed. In addition, since the reflector 220 may actually comprise a group (or an array) of reflectors, opportunities to recycle light may be realized based on local dimming. In one possible embodiment, when not all available light is needed to form the final projected image, light recycling may be employed based on global or local dimming, and then used based on the target, e.g., projecting a "highlight" in the final projected image. Highlight may be a portion of an image where it is desirable to introduce a larger amount of brighter energy than the surrounding portions of the image in order to emphasize that portion.
In another embodiment, light recovery may also be used based on global dimming or local dimming to increase the brightness of an image or scene, i.e. on average brighter than the previous image or scene. These opportunities may occur during illumination of either the pre-modulator/first modulator stage or the primary modulator/second modulator stage, as can be seen in fig. 6B.
In one embodiment, the projector system may determine how best to employ light recycling by the controller in processing the input image/video data. The decision to recycle can be made either at the time of processing the image data or in advance in a look-ahead (look-ahead) manner, frame by frame, group of frames, or scene by scene. In another embodiment, the entire video and/or scene may be analyzed offline, and control signals may be sent to the controller as part of the associated metadata stream along with the image/video data.
FIG. 7A is one embodiment of a flow chart for performing light recycling. The control system/method 700 may input image data at 702. Based on the response curve and/or table (e.g., as shown in fig. 7B), the system/method may calculate an Average Picture Level (APL) for each Individual Modulation Color (IMC) of the modulator. As can be seen from the graph of fig. 7B, each individual color may exhibit a different relative brightness for a given DMD fill percentage. It may be desirable to take these color differences into account when performing light recycling to eliminate and/or mitigate visual artifacts of any hue. It should be understood that the flow charts of fig. 7A and 8 may assume that the recovery produces a uniform light field, while the flow chart of fig. 9 may account for spatial intensity variations due to the recovery and employ the tables of fig. 7C and 10. For example, according to the table depicted in fig. 7C, the input image may be divided into a 5 × 4 array of image areas, and the light recovery in each image area may be adjusted from 0% to 40% as shown.
Returning to FIG. 7A, at 706, the system/method may determine a relative brightness increase for each IMC. Once completed, the system/method may instruct the display system to reduce the illumination light source intensity to the inverse of the brightness increase for each IMC. It should be understood that other functional relationships between the illumination light source intensity and the increase in brightness are possible and/or desirable, such as some inverse relationship to some function of the increase in brightness. Where the term "inverse" is used herein, it should be understood that such other embodiments are also possible. The light source intensity may be adjusted at 708, but in some embodiments, the recovery may remain unchanged (e.g., the percentage of recovery may not change due to light source reduction, only the absolute value, so as not to place too much illumination on the modulator). Since the light travels quickly, and even the fastest PWM period is relatively slow, recycling can be considered instantaneous and the resulting illumination level can be achieved immediately after the modulator switches to its current state.
Where the system employs one or more DMDs as the primary modulator (e.g., a modulator that spreads out the modulation over several time periods), there may be a modulator state and resulting recovery level for each time period, and each of them may be calculated and compensated for. For systems employing one or more DMDs as the pre-modulators, there may be only one time period, as the system may drive these pre-modulators using a halftone binary pattern, which may change only once per frame (e.g., may actually change 1 to 4 times per frame, but this may be significantly less than 10 to 100 times the time period of the master DMD modulator (10's-100's)). In embodiments employing LCDs and LCoS as primary modulators, these primary modulators may switch slowly (relative to the DMD) at display time, so the resulting recoveries may be integrated over that time to determine how to compensate.
While the control system/method of fig. 7A may generally function in any dual modulator/multi-modulator display system, the control may also function in the context of a single modulator projector system (e.g., may be constructed in the same or similar manner as fig. 1B). The recovery on the primary modulator may come from the timing nature of DMD, LCoS, and LCD based systems.
Fig. 8 is yet another control system/method (800) for light recycling. Control may begin inputting image data at 802. At 804, the system may calculate an APL for each IMC. The system may then determine a relative brightness increase for each IMC at 806. At 808, the system may reduce the illumination light source intensity to the closest setting of the inverse of the increase in brightness, possibly no lower than the inverse value, for each IMC. In one embodiment, it may be assumed that the system may use the modulator to reduce light, but not increase light, in which case it may not be desirable for the system to reduce the illumination source below the required level. However, in another embodiment (e.g., in the case of most dark modulator images), the opposite is often true (e.g., the system may reduce the illumination and then set the modulator to allow more light to pass). In this case, step 808 may continue to reduce the illumination light source intensity to the setting closest to the inverse of the brightness increase for each IMC and still allow modulator compensation.
The system may then reduce the intensity of the image driven to the modulator at 810 to compensate for the difference between: the desired inverse of the increase in brightness, and the settings achievable with the illumination source. Alternatively, step 810 may also adjust the intensity of the image driven to the modulator to compensate for the difference between: the desired inverse of the increase in brightness, and the settings achievable with the illumination source.
Fig. 9 is yet another embodiment of a control system/method for light recycling. However, the control system/method may function well in display systems where light non-uniformities caused by recycling may need to be considered and/or adjusted, and the illumination intensity control is fine-grained or continuous. The system/method 900 may input image data at 902. At 904, the system may calculate an APL for each region of the IMC (i.e., the image may be divided into different regions). At 906, the system may determine a relative brightness increase for each region in each IMC based on the experimental statistics. The system can drive patterns (e.g., some regions off and the rest on) to the modulator and observe the distribution of light. Depending on the location of the dark area, the light it recovers may return to the modulator in a non-uniform manner. This non-uniformity needs to be compensated for at the modulator.
At 908, the system may reduce the illumination light source intensity to the inverse of the region with the lowest brightness increase for each IMC. The system may determine a relative brightness increase for each region in each IMC based on the illumination light source intensity setting. Then, at 912, the system may reduce the intensity of the image driven to each region of the modulator to compensate for the difference between: the desired inverse of the increase in brightness for that region, and the settings of the illumination source.
Given an input image divided into an array of 5 x 4 image areas, fig. 10 depicts an example table that is partially filled (e.g., center and corner values are filled only by measurement, estimation, and/or calculation, the remainder may be similarly filled) for setting the non-uniform level of light recovery across the modulator given a certain modulator area pattern (e.g., derived as part of experimental statistics). In another aspect, the pattern may be displayed and then the resulting level of recovery adjusted based on its characteristics. For example, table 1 shows the luminance characteristics of an image divided into a 3 × 3 array of image areas (e.g., in each area it shows whether the average or peak luminance level is above or below a predetermined luminance threshold (e.g., 10 nits)). For example, since the lower right region is off (or below the threshold), in an embodiment, as shown in table 2, most of the light recycling may be performed near this region and then reduced for image regions located further away. Many such tables derived experimentally may be used at 906.
TABLE 1-luminance characteristics of test images segmented into 3X 3 array of image regions
Is opened | Is opened | Is opened |
Is opened | Is opened | Is opened |
Is opened | Is opened | Close off |
TABLE 2-percentage of light recovery for an image divided into 3X 3, according to image characteristics
102% | 104% | 108% |
103% | 108% | 109% |
104% | 108% | 110% |
FIG. 11 is one embodiment of an algorithm (1100) for reducing the intensity of an illumination light source as a function of brightness increase. In some systems, this increase in brightness may be produced based on individually modulating the colors.
At 1102, the system can input a desired image for viewing. At 1104, the system may calculate a desired (or otherwise required) light field to be generated by the pre-modulator for each Individual Modulation Color (IMC). At 1106, the system may calculate an Average Picture Level (APL) for the pre-modulators of each IMC. At 1108, a relative brightness increase may be determined for each IMC based on its APL. At 1110, the system may then reduce the illumination light source intensity to the inverse of the brightness increase for each IMC.
FIG. 12 is one embodiment of an algorithm (1200) for reducing the intensity of an illumination light source, particularly in systems that may employ polarization to project an image, for example, as can be seen from FIG. 5.
At 1202, the system can input a desired image for viewing. At 1204, the system may calculate, possibly for each IMC, an amount of light (e.g., 514 in fig. 5) to be directly diverted to the primary modulator. At 1206, the system may then calculate the light field to be generated by the pre-modulators of each IMC. The APL may then be calculated for the pre-modulator of each IMC at 1208. The system may then determine a relative brightness increase based on its APL for each IMC at 1210. At 1212, the system may reduce the illumination light source intensity to the inverse of the increase in brightness for each IMC. This may also include the amount of light to be diverted directly to the primary modulator for each IMC. At 1214, the system may then adjust the polarizer (e.g., 505) to align the polarization to the beam splitter (e.g., 506) so that the desired amount of light may be diverted directly to the primary modulator.
FIG. 13 is one embodiment of an algorithm (1300) that can input the generated image without assuming that the display system can participate in light recycling. In one embodiment, the system may adjust light recycling in many possible ways, for example, taking an "EDR Master" level and mapping it to the capabilities of the target display while preserving artistic intent through metadata.
At 1302, the system can input a desired image for viewing. The image may be created assuming that no recycling is to be achieved. At 1304, the system may calculate an APL for each IMC. At 1306, the system may determine a relative brightness increase for each IMC based on its APL. The system may then provide (or otherwise calculate) the range of luminance achievable for each IMC to the display management algorithm at 1308. At 1310, the display management algorithm may generate an image to display based on a recycling range, which may be lower-but possibly not higher-luminance than achievable for each IMC using recycling. At 1312, the system may then calculate a new apl (napl) for each IMC. At 1314, the system may determine a new relative brightness increase for each IMC based on its NAPL. Thereafter, the system may reduce the illumination light source intensity to the inverse of NAPL for each IMC at 1316.
Relay optics for high dynamic range projector systems
With continued reference to fig. 14, fig. 14 shows relay optics 1418 placed between a first modulator 1416 (e.g., a pre-modulator) and a second modulator 1420 (e.g., a primary modulator). Such a relay optical system may be desirable to both reduce the amount of artifacts in image processing and increase the contrast of the projected image.
As discussed herein in the context of one embodiment, it may be desirable for the first modulator/pre-modulator to produce a blurred and/or defocused image based on image data values (e.g., the halftone images mentioned herein). In many embodiments, it may be desirable to have a relay optical system that tends to generate a uniformly blurred/defocused image from the pre-modulator to the primary modulator. Further, with the present embodiment, it may be desirable to have a spot shape with a desired defocus.
In many embodiments, the relay optical system may include a lens or other optical element that effectively moves the focal plane, corrects for any coma (coma), and adjusts for diffusion (e.g., by producing defocus/blur, and adding up to some desired amount of spherical aberration).
For example, fig. 15 depicts one possible desired spot shape 1502 of a substantially gaussian shape, where the x-axis is distance (in mm) and the y-axis is relative amount illumination (e.g., "1" is maximum illumination and "0" is dark). It should be noted that in systems where light recycling may be provided or other systems/methods where highlights are provided, the illumination may exceed "1" at one time or another.
In addition to the optical system 1418 of fig. 14, fig. 16 is another embodiment of a relay optical system 1600 suitable for the purposes of the present application. On either end of relay optical system 1600, two modulators, e.g., 1602a and 1602b, may be provided (e.g., an unfolded prism system as shown in fig. 16). The first modulator 1602a may be a pre-modulator and the second modulator 1602b may be a primary modulator, as further mentioned herein.
The light transmitted by the first modulator 1602a may further pass through a focusing lens group 1604, a coma correction lens group 1606, and a field flattening/spherical aberration inducing lens group 1608 before illuminating the second modulator 1602 b. In many embodiments, the relay optical system may be substantially telecentric, for example, wherein the chief rays (i.e., the oblique rays passing through the center of the aperture stop) are substantially parallel to the optical axis, respectively, in front of or behind the system.
Fig. 17 and 18 depict embodiments of a focus group 1604 and a coma correction lens group 1606, respectively. As can be seen in fig. 17, light from the first modulator 1602a is transmitted to the focal group 1604. The focusing group 1604 may also include a first lens 1604a, which may be a plano-convex lens. The lenses 1604b and 1604c may be two lenses including a plano-convex lens or a lens containing a slight meniscus.
Each of these lenses may be designed to have a desired amount of spherical aberration which, in combination with defocus, may produce an appropriate light distribution at the image plane where the primary modulator is located (as shown in fig. 15). A plurality of weak lenses, rather than fewer elements with higher power, will more readily produce the desired amount of spherical aberration. The distance between the lens elements may also help to achieve a desired amount of these aberrations.
As described above, the amount of blurring and/or defocusing may be set and/or controlled according to the distance between the lenses 1604a and 1604 b. In one embodiment, a distance of about 5mm to 9mm and/or an air gap may be suitable to provide sufficient defocus/blur for illuminating the second modulator. Another embodiment of the focus group 1604 may affect the ability to vary the focus by changing the air spacing between the two elements, thereby adjusting the spot size at the primary modulator. In this respect, the focus that can be adjusted with the elements also tends to produce the desired spherical aberration.
In one embodiment, the projector system may set the distance once at the time of manufacture, and the lens may be set on a permanent mount during the operational life of the projector system. In another embodiment, the distance may be dynamically changed during operation. In such embodiments, one or more lenses may be movably mounted in the relay optical system, wherein the distance may be adjusted as needed according to a controller providing control signals to the movable mount.
Fig. 18 depicts light from the focus group 1604 being transmitted to the coma correction group 1606. As in several embodiments of the present projection system, the fact that light is transmitted between two modulators (which may include optical elements that are tilted with respect to each other) (e.g., two modulators that include a plurality of prisms, etc.), may tend to cause some amount of coma and/or aberration in the transmitted light. Thus, in many embodiments, a coma correction group 1606 may be placed in the optical path to correct such coma and/or aberration. By shifting the optical axis 1607a in the first lens 1606a by a desired amount relative to the optical axis 1607b in the second lens 1606b, a way of correcting coma/aberration can be achieved, as can be seen in fig. 18. In one embodiment, both lenses 1606a and 1606b can be slightly meniscus, e.g., with the surface near the optical path being slightly concave and the surface away from the optical path being slightly convex. One or both of lenses 1606a and 1606b may be plano-convex lenses.
In addition, the coma correction group 1606 can be designed to provide color correction in light, e.g., such that the projector system can employ multiple colors of light (e.g., red, green, and blue) in the following manner: provides a uniform magnification and avoids the use of any additional corrective optical elements. If the positive elements (positive elements) are made of crown glass (crown glass) with low dispersion and the negative elements (negative elements) of the set 1606 are made of flint glass (flint glass) with high dispersion, the glass and element shapes can be chosen such that all light wavelengths are focused almost equally at the primary modulator. This feature may also provide the same magnification for each color so that in a three-color projector, the optical path of the optical system of fig. 16 may be made the same for each color.
Light from the coma correcting group 1606 can be transmitted to the field flattening/spherical aberration causing group 1608. The set 1608 may be employed to provide additional spherical aberration to provide additional defocus/blur to the point spread function (PSF, e.g., substantially gaussian) of the light transmitted to the second modulator.
In some embodiments, there may be a relay optical system that may have one, two, or three functional groups for different arrangements. For example, one relay optical system may include different combinations of focus groups, coma correction groups, and/or groups that cause spherical aberration.
Relay optical system for projector system using light recovery
In a projector system employing a light recovery system as discussed herein, fig. 19 illustrates one possible embodiment that includes a first modulator 1602a, a second modulator 1602b, and a relay optical system that may include a focus group 2004, a coma correction group 2006, and a spherical aberration causing group 2008. The focus group 2004 and the coma correction group 2006 and the group causing spherical aberration 2008 may function, and may be set substantially the same as described above without light recovery.
However, in systems employing light recycling, it may be desirable for the light from the first modulator 1602a to have different angles of incidence to the optical path entering the relay optical system (as depicted by the light transmitted from the surface 2001 of 1602 a). To correct for this angle of incidence, a prism 2010 may be placed proximal to the second modulator 1602 b. This may be because the light that exits the object (pre-modulator 1602a) is at an incident angle of substantially 36 degrees (referred to as the main light angle in this case) with respect to the pre-modulator 1602a, and the light reaches the main modulator 1602b at an incident angle of 24 degrees. This tends to result in a loss of symmetry in the optical path, which would not occur without recycling. It may be desirable that the light path (both glass and air) for light traveling from all corners of the object plane to the image plane is substantially the same. Where the image plane is found to be tilted relative to the primary modulator 1602b, a glass wedge 2010 may be added to one or more prisms in the optical path, the shape of such wedge being determined by optimizing the design in view of the focus group 2004, the coma group 2006, and the aberration group 2008.
Fig. 20 depicts the etendue (etendue) of a light source, for example, if there are multiple optical fibers illuminating the light path. For example, in fig. 14, there may be more than one optical fiber to provide illumination. Light that can be delivered to a small spot or a single fiber may be preferred over light delivered to a large spot or multiple fibers. Fig. 20 illustrates a potential tradeoff in recovery efficiency. It may be desirable to provide the largest possible area of the input face of the integrator rod to be covered by the reflector rather than the port.
A detailed description of one or more embodiments of the invention has now been given, read in conjunction with the accompanying drawings, illustrating the principles of the invention. It should be understood that while the invention is described in conjunction with such embodiments, the invention is not limited to any embodiment. The scope of the invention is limited only by the claims and the invention encompasses numerous alternatives, modifications and equivalents. In the description, numerous specific details have been set forth in order to provide a thorough understanding of the present invention. These details are provided for the purpose of example and the invention may be practiced according to the claims without some or all of these specific details. For the purpose of clarity, technical material that is known in the technical fields related to the invention has not been described in detail so that the invention is not unnecessarily obscured.
Further, the present invention can also be configured as follows.
(1) A projector display system capable of recycling light from a light source, the projector display system comprising:
a light source;
an integrating rod configured to receive light from the light source at a proximal end, and wherein the proximal end comprises a reflective surface capable of reflecting light along the integrating rod;
a relay optical system further comprising an optical element capable of moving a focal plane of the projector display system; and
a modulator comprising a movable mirror capable of reflecting light received from the integrating rod in at least one of a projection direction and a light recovery direction, wherein the light recovery direction is substantially along the direction of the integrating rod.
(2) The projector display system of above wherein said light source is one of the group consisting of: laser, partially coherent light, colored partially coherent light, LED, xenon lamp.
(3) The projector display system according to above, wherein the projector further comprises:
a first modulator comprising a plurality of movable mirrors capable of reflecting light received from the integrating rod in at least one of a first projection direction and a light recovery direction, wherein the light recovery direction is substantially along the direction of the integrating rod; and
a second modulator capable of modulating light received from the first modulator in the first projection direction and transmitting the modulated light for projection.
(4) The projection display system of above, wherein the first modulator comprises a pre-modulator.
(5) The projection display system according to above, wherein the pre-modulator is capable of generating a halftone image of a desired image to be displayed.
(6) The projection display system of above wherein the second modulator comprises a primary modulator.
(7) The projection display system according to above, wherein the primary modulator is capable of pulse width modulating the halftone image produced by the pre-modulator.
(8) The projector display system of above wherein said first modulator comprises a highlight modulator.
(9) The projector display system of above wherein said highlight modulator is capable of placing additional light energy in the main beam to highlight a desired portion of the image to be displayed.
(10) The projector display system of above wherein said second modulator is capable of modulating said main beam and said additional light energy to produce a desired image.
(11) The projector display system of above wherein said light source comprises a plurality of color light sources; and
an integrating rod for each color light source, the integrating rod configured to receive light from the light source at a proximal end, and wherein the proximal end comprises a reflective surface capable of reflecting light along the integrating rod; and
a modulator for each color light source, the modulator comprising a movable mirror capable of reflecting light received from the integrating rod in at least one of a projection direction and a light recovery direction, wherein the light recovery direction is substantially along the direction of the integrating rod.
(12) The projector display system as described above, wherein said projector display system further comprises:
a dichroic combiner capable of combining at least two color beams from at least two integrator rods to form a primary beam.
Claims (10)
1. A projector display system comprising:
a light source;
a controller that receives input image data and transmits a control signal in response to the input image data;
a first modulator controllable by the control signal from the controller and configured to generate a blurred image based on the input image data;
a relay optical system configured to receive a blurred image from the first modulator and further configured to provide a desired amount of defocus of the blurred image to provide a plurality of substantially Gaussian spots; and
a second modulator configured to receive the plurality of Gaussian spots and further modulate the light to produce an image for further projection,
wherein the relay optical system includes a plurality of optical elements including a lens group that causes spherical aberration.
2. The projector display system of claim 1 wherein said light source is one of the group consisting of: laser, partially coherent light, colored partially coherent light, LED, xenon lamp.
3. The projector display system of claim 2 wherein said plurality of optical elements are configured to move a focal plane by an appropriate amount to produce said desired amount of defocus.
4. The projector display system of claim 3 wherein said plurality of optical elements further comprises:
a focusing lens group; and
a coma correcting lens group.
5. The projector display system of claim 4 wherein said plurality of optical elements are substantially telecentric.
6. The projector display system of claim 5 wherein said focusing lens group further comprises a first plano-convex lens and a set of second lenses comprising one of the group consisting of: plano-convex lenses, and lenses comprising a slight meniscus.
7. The projector display system of claim 6 wherein a desired distance between said first plano-convex lens and said set of second lenses is set to produce said desired amount of defocus.
8. The projector display system of claim 7 wherein said coma correcting lens group comprises at least a first lens and a second lens, wherein further an optical axis of said second lens is offset from an optical axis of said first lens to produce a desired amount of coma correction.
9. The projector display system of claim 1 wherein said spherical aberration inducing lens group further comprises a plurality of lenses for providing additional spherical aberration to provide a desired point spread function to light sent to said second modulator.
10. The projector display system of claim 1 wherein said projector display system further comprises a prism proximate said relay optical system, said prism configured to correct an angle of incidence of light exiting said first modulator.
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JP2018503126A (en) | 2018-02-01 |
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JP2020144389A (en) | 2020-09-10 |
US10386709B2 (en) | 2019-08-20 |
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